Syllabus Edition

First teaching 2020

Last exams 2024

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Linear Momentum & Conservation (CIE AS Physics)

Exam Questions

3 hours41 questions
1a
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2 marks

State the principle of conservation of linear momentum.

1b
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2 marks

A pellet of mass 20 g is fired from an air rifle with a momentum of 1.2 kg m s−1.

Calculate the velocity of the bullet just after the rifle is fired.
1c
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2 marks
Use the principle of conservation of momentum to state:
 

(i)
the total momentum of the air rifle and the pellet,
[1]
 
(ii)
the recoil momentum of the air rifle.
[1]

1d
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4 marks

The pellet hits a target. It becomes embedded and takes 0.0025 s to come to rest. 

(i)
State the relation between force and momentum.
[1]
 
(ii)
Calculate the average force needed to stop the pellet.
[3]

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2a
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3 marks

A collision can be described as being elastic or inelastic when there are no external forces acting on the collision.

In Table 1.1, place a tick (✓) next to the quantities that are conserved in each type of collision

 

Table 1.1

Quantity

Elastic Collision

Inelastic Collision

Momentum

   

Total Energy

   

Kinetic Energy

   

 

2b
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3 marks

A trolley X with mass of 400 g is moving on a track with a velocity of 1.2 m s−1 towards a stationary trolley Y with mass of 800 g as shown in Fig. 1.1.

3-2-2b-e-momentum-trolley-collision-cie-ial-sq

Fig. 1.1

(i)
Calculate the initial momentum of trolley X.
[2]
 
(ii)
Trolley X collides with trolley Y and subsequently, they stick together.
 
State the combined momentum of the trolleys after the collision.
[1]
2c
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4 marks
(i)
Calculate the velocity of the two trucks after the collision.
[3]
 
(ii)
State the direction of the velocity of the trolleys after the collision.
[1]
2d
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1 mark

Explain why the collision cannot be described as elastic.

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3a
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2 marks

State the difference between an elastic and an inelastic collision.

3b
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2 marks

A ball collides with a wall at a velocity of 35 m s−1 and rebounds with velocity v. The ball has a mass of 0.025 kg.

The motion of the ball is shown in Fig. 1.1.3-2-3b-e-momentum-ball-rebound-cie-ial-sq

Fig. 1.1

 

Calculate the momentum of the ball at the start, before it hits the wall.

3c
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3 marks

The collision is perfectly elastic.

Determine

 
(i)
the rebound velocity of the ball
[1]
(ii)
the magnitude of the change in momentum of the ball.
[2]
3d
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2 marks

The ball is in contact with the wall for 0.1 s.

Calculate the force exerted on the ball by the wall.

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1a
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3 marks

A ball X of mass 140 g travelling at constant velocity v collides head-on with a stationary ball Y of mass 620 g, as shown in Fig. 1.1.

3-2-1a-m-3-2-ball-x-y-conservation-of-momentum-cie-ial-sq

After the collision, ball X comes to a stop. Ball Y moves off in the same initial direction as X with a velocity of 0.8 m s−1.

Determine the velocity v of ball X before the collision.

 
1b
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4 marks
(i)
Show that the collision in (a) is inelastic.
[3]
(ii)
Explain why the collision in (a) is inelastic.
[1]
1c
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3 marks

The balls are replaced by an aluminium sphere of mass 2.7 kg and a steel sphere of 7.9 kg as shown in Fig. 1.2.

The aluminium sphere has an initial velocity of 10.0 m s–1 when it collides with the stationary steel sphere. Immediately after the collision, the velocity of the steel sphere is 5.1 m s–1.

3-2-1c-m-3-2-metal-spheres-conservation-of-momentum-cie-ial-sq

Calculate the velocity v of the aluminium sphere immediately after the collision.

1d
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3 marks

Verify that the collision in (c) is elastic.

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2a
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3 marks

Two identical blocks A and B each of mass 400 g are travelling towards each other along a straight line through their centre, as shown in Fig. 1.1.

3-2-2a-m-3-2-momentum-blocks-same-speed-cie-ial-sq

Both blocks are moving at a speed of 0.36 m s–1 relative to the surface.

As a result of the collision, the blocks reverse their direction of motion and travel at the same speed as each other. During the collision, 33% of the kinetic energy of the blocks is transferred to the surroundings as thermal energy.

(i)
State the total momentum of the blocks before the collision.
[1]
(ii)
State and explain whether the collision is elastic or inelastic.
[2]
2b
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3 marks

Calculate the final speed of the blocks.

2c
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3 marks

The duration of the collision between the blocks is 750 ms.

Determine the average force exerted by one block on the other.

2d
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4 marks

The same blocks are investigated with different initial speeds. Block A is launched towards B at a speed of 0.6 m s−1 and B is launched towards A at a speed of 0.4 m s−1.

Once the blocks collide, they stick together and move as one after the collision.

Determine the speed of the combined blocks after the collision and state the direction.

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3a
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4 marks

A fast-moving asteroid B collides with a slower-moving asteroid A as shown in Fig. 1.1. Asteroid B becomes embedded within asteroid A as shown.

3-2-3a-m-3-2-linear-momentum-asteroid-collision-cie-ial-sq

Before the collision, asteroid A had a velocity of 3.61 km s−1 and a momentum of 2.00 × 1017 kg m s−1.

(i)
State the principle of conservation of linear momentum.
[2]
(ii)
Show that the mass of asteroid A was about 5.5 × 1013 kg.
[2]
3b
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3 marks

Calculate the combined velocity, in km s−1, of the asteroids after the collision.

mass of asteroid B = 6.40 × 1012 kg
velocity of asteroid B before the collision = 14.0 km s−1

3c
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4 marks

A short time later, the combined asteroid AB collides with a stationary asteroid C. Immediately following the collision, the asteroids are deflected by the angles shown in Fig. 1.2.

3-2-3c-m-3-2-momentum-asteroid-collision-2d-cie-ial-sq

Show that the mass of asteroid C is about 1.0 × 1013 kg.

3d
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3 marks

Determine if the collision in (c) is elastic or inelastic.

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4a
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2 marks

Ball X has a mass of 50 g and is supported by a long string, as shown in Fig. 1.1.

cie-ial-3-2-q4a-conservation-of-momentum-ball-and-wall

Fig. 1.1

The ball is pulled back and released. The ball collides normally with a flat surface at a velocity of 4.5 m s−1 and rebounds elastically.

The positive direction is horizontal and to the right.

Determine the total change in momentum of ball X. 

4b
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3 marks

Ball X is hung next to ball Y which is supported by a string of the same length, as shown in Fig. 1.2.

cie-ial-3-2-q4b-conservation-of-momentum-two-balls

Fig. 1.2

Ball Y has a mass of 125 g.

The balls are each pulled back and pushed towards each other. When the balls collide, the strings are vertical. The balls rebound in opposite directions.

The velocities of X and Y just before and just after the collision are shown in Fig. 1.2.

Use the conservation of linear momentum to determine the rebound velocity v of Y.

4c
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2 marks

Deduce whether the collision, in part (b), is elastic or inelastic.

4d
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3 marks

Use Newton’s laws to explain why the magnitude of the change in momentum of each ball is the same.

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5a
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2 marks

A shell of mass 30 g is fired from the barrel of a rifle of mass 1.9 kg. Immediately after being fired, the bullet has a momentum of 36 kg m s−1.

State the total momentum of the rifle and the bullet before the rifle is fired and give a reason for your answer.

5b
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2 marks

Calculate the velocity of the shell just after the rifle is fired.

5c
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3 marks
(i)
Using the principle of conservation of momentum, and your answer to part (a), determine the total momentum of the rifle and the shell.
[1]
(ii)
Calculate the recoil momentum of the rifle.
[2]
5d
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3 marks

The shell has a momentum of 9.8 kg m s−1 just before it hits a target.

It takes 4.5 ms for the bullet to the stopped by the target.

Calculate the average force needed to stop the bullet.

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1a
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3 marks

A stationary firework explodes into three different fragments that move in a horizontal plane. Fig. 1.1. shows the masses and velocities of the fragments A, B and C in terms of M and v.

3-2-1a-h-momentum-explosion-unequal-fragments-cie-ial-sq

Fig. 1.1

Use the principle of conservation of momentum to determine the speed v subscript B of fragment B in terms of v.
1b
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3 marks

Use the principle of conservation of momentum to determine the angle θ.

1c
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4 marks

Another stationary firework explodes into four fragments which travel in different directions in a horizontal plane.

Fig. 1.2 shows the velocity and mass of each fragment.

3-2-1c-h-momentum-explosion-four-unequal-fragments-cie-ial-sqa

Fig. 1.2

Apply the principle of conservation of momentum to determine
 
(i)
the velocity v subscript 2
[2]
(ii)
the mass m subscript 3
[2]
1d
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4 marks

Both fireworks have the same initial mass and release the same amount of kinetic energy.

Calculate
 
(i)
the value of M
[1]
(ii)
the magnitude of v.

[3]

1e
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8 marks

Challenge

A firework similar to the one in (c) explodes into four fragments.

Fig. 1.3 shows the velocity and mass of each fragment.

3-2-1c-h-momentum-explosion-four-unequal-fragments-cie-ial-sq

Fig. 1.3

(i)
By applying the principle of conservation of momentum, show that
 

m subscript 1 over m subscript 2 space equals space v subscript 3 over v subscript 4 space equals space 3 over 5

m subscript 3 over m subscript 4 space equals space v subscript 1 over v subscript 2 space equals space 2 over 3

[6]

(ii)
Hence, determine the values of m subscript 2v subscript 2m subscript 3 and v subscript 3.
[2]

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2a
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4 marks

A pellet of mass 2.7 g is fired into a stationary block of mass 540 g suspended from a rigid support as shown in Fig. 1.1.

The pellet becomes completely embedded in the block. The block can swing freely at the end of a light inextensible string of length 1.5 m measured from the pivot to the centre of the block. 

qu-5b-figure-2

Fig. 1.1

The centre of mass of the block rises by a height h at an angle of 35° to the vertical. 

Determine the velocity of the pellet and the block immediately after the pellet is embedded.

2b
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3 marks

Calculate the velocity of the pellet just before it strikes the block. 

2c
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6 marks

The block is replaced by a metal block of the same mass. The experiment is repeated with the wooden block and an identical pellet. The pellet rebounds after striking the block.

A student makes an assumption that the angle that the metal block makes with the vertical will be greater than 35° because the block doesn’t have the additional mass of the pellet embedded within it.

Discuss the validity of the student's assumptions.

2d
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5 marks

A popular demonstration of the conservation of momentum and conservation of energy is Newton’s cradle. It features several identical polished steel balls hung in a straight line in contact with each other, as shown in Fig. 1.2.

If one ball is pulled back and allowed to strike the line, one ball is released from the other end whilst the rest are stationary. If two are pulled out, two are released on the other end and so forth.

qu-5a-figure-1

Fig. 1.2

Explain why swinging one ball from the left will not release two balls on the right. 

Assume that the demonstration takes place in a vacuum.

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3a
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2 marks

A body of mass M and moving with velocity V explodes into three equal fragments each of mass M over 3, as shown in Fig. 1.1.

3-2-3a-h-momentum-explosion-equal-fragments-cie-ial-sq

Fig. 1.1

Fragment 2 continues to move along the horizontal plane with velocity v subscript 2, while fragments 1 and 3 move off at an angle of 60° to the horizontal with velocities v subscript 1 and v subscript 3 respectively, as shown. 

By applying the principle of conservation of momentum in the vertical plane, show that  v subscript 1 space equals space v subscript 3

3b
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3 marks

By applying conservation of momentum in the horizontal plane, show that  3 V space equals space open parentheses v subscript 1 space plus space v subscript 2 close parentheses

3c
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4 marks

The ratio of the kinetic energy of fragment 1 to mass M is

fraction numerator k i n e t i c space e n e r g y space o f space f r a g m e n t space 1 over denominator k i n e t i c space e n e r g y space o f space m a s s space M end fraction space equals space 4 over 3

Express velocities v subscript 1 and v subscript 2 in terms of the velocity V of mass M.
3d
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4 marks
(i)
Determine the total kinetic energy transferred to the fragments.
[3]
(ii)
Suggest why the total kinetic energy of the fragments is greater than the initial kinetic energy of the original mass.
[1]

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